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United States Patent |
5,230,415
|
Ament
,   et al.
|
July 27, 1993
|
Clutch plate for a motor vehicle friction clutch
Abstract
In order to mount the lateral discs of a clutch plate, provided with a
torsional vibration damper, of a motor vehicle friction clutch on a hub,
there is provided a plastic ring (23) which is inserted with an annular
part (29) into a central opening in one of the lateral discs. The plastics
ring (23) has a plurality of sets of radially inwardly projecting blocks
(41, 43, 45), separated from one another by slots (46), with a cylindrical
segment-shaped internal contour (47). The blocks (41) of a first set are
radially resilient and define an internal diameter (D1) such that these
blocks can rest without radial pretension on the external contour of the
hub. The blocks (43) of a second set pass into the noses (33) provided to
prevent rotation and, like the blocks (45) of a third set, are not
resilient. The blocks (43, 45) of the second and third set define internal
diameters (D1, D3) which are greater than the internal diameter (D1) of
the first set, the internal diameter (D3) of the third set being smaller
than the internal diameter (D2) of the second set. The blocks (45) of the
third set rest via the annular part (29) directly on the central opening
of the lateral disc and restrict the spring travel of the radially
resilient blocks (41) of the first set. The blocks (43) of the second set
which are not directly radially supported owing to radial tolerances of
the lateral discs in the region of the noses (33) are therefore used to
restrict the spring travel of the blocks (41) of the first set only after
the blocks (45) of the third set are worn.
Inventors:
|
Ament; Norbert (Werneck, DE);
Raab; Harald (Schweinfurt, DE)
|
Assignee:
|
Fichtel & Sachs AG (Schweinfurt, DE)
|
Appl. No.:
|
977818 |
Filed:
|
November 17, 1992 |
Foreign Application Priority Data
Current U.S. Class: |
192/204; 192/214.1; 464/68.6 |
Intern'l Class: |
F16D 003/66 |
Field of Search: |
192/106.2
464/63,68
|
References Cited
U.S. Patent Documents
4453838 | Jun., 1984 | Loizeau | 192/106.
|
4635780 | Jan., 1987 | Wiggen | 192/106.
|
4763767 | Aug., 1988 | Lanzarini et al. | 192/106.
|
4889218 | Dec., 1989 | Chasseguet et al. | 464/68.
|
4890712 | Jan., 1990 | Maucher et al. | 192/106.
|
4899862 | Feb., 1990 | Graton et al. | 192/106.
|
4998608 | Mar., 1991 | Raab et al. | 192/106.
|
5000304 | Mar., 1991 | Kock et al. | 192/106.
|
5014842 | May., 1991 | Graton et al. | 192/106.
|
5016744 | May., 1991 | Fischer et al. | 192/106.
|
5064041 | Nov., 1991 | Graton et al. | 192/106.
|
5117959 | Jun., 1992 | Graton | 192/106.
|
5145463 | Sep., 1992 | Bacher et al. | 464/63.
|
5169357 | Dec., 1992 | Graton | 464/68.
|
Foreign Patent Documents |
2642804 | Aug., 1990 | FR | 192/106.
|
63-9729 | Jan., 1988 | JP | 192/106.
|
Primary Examiner: Bonck; Rodney H.
Assistant Examiner: Pitts; Andrea
Attorney, Agent or Firm: Brumbaugh, Graves, Donohue & Raymond
Claims
What we claim is:
1. A clutch plate for a motor vehicle friction clutch, comprising:
a hub (3) concentric to an axis of rotation (1)
a hub disc (5) non-rotatably connected to the hub (3)
lateral discs (7, 9) which are arranged axially on either side of the hub
disc (5), are rigidly connected to one another, are rotatable relative to
the hub disc (5), are torsionally elastically coupled to the hub disc (5)
by means of springs (15) and of which one lateral disc (7) has a central
opening (27) with which this lateral disc (7) surrounds a circular
cylindrical external face (25) of the hub (3),
a plastic ring (23), radially guiding said one lateral disc (7) on the hub
(3), with an annularly closed annular part (29) inserted into the central
opening (27) of said one lateral disc (7), with a web part (31) which
projects radially outwardly from the annular part (29) and forms an axial
stop resting on said one lateral disc (7), with at least one nose (33)
which projects radially outwardly from the annular part (29) and engages
in a radial recess (35) of the central opening (27) to prevent rotation
and with a plurality of sets of peripherally distributed blocks (41, 43,
45) which are separated from one another by radial slots (46), project
radially inwardly from the annular part (29) and each have a cylindrical
segmentshaped internal contour (47) radially adjacent to the circular
cylindrical external face (25) of the hub (3), wherein the blocks (41) of
a first set are radially resilient in design and each have a web (49)
which forms the cylindrical segment-shaped internal contour (47) and
extends substantially in a direction of the axis of rotation (1), is
connected via a connecting region (51) to an axial edge region of the
annular part (29) and rests with the cylindrical segment-shaped internal
contour (47) without radial prestress on the circular cylindrical external
(25) of the hub (3), and wherein the blocks (43) of a second set are
radially non-resilient in design and extend radially outwardly beyond the
annular part (29) to form noses (33), wherein the internal contour of the
blocks (43) of the second set define a greater internal diameter than the
blocks (41) of the first set,
wherein the blocks (45) of a third set are alsc radially non-resilient in
design and the internal contour of the blocks (45) of the third set define
an internal diameter which is greater than the internal diameter defined
by the internal contour (47) of the blocks (41) of the first set but
smaller than the internal diameter defined by the internal contour of the
blocks (43) of the second set.
2. The clutch plate as in claim 1,
wherein, sequentially in a peripheral direction, each block (41) of the
first set is followed by a block (43, 45) alternately of the second set
and of the third set.
3. The clutch plate as in claim 2, wherein
the first set comprises eight blocks (41) and the second and third set each
comprises four blocks (43, 45) each.
Description
BACKGROUND OF THE INVENTION
The invention relates to a clutch plate for a motor vehicle friction
clutch, and in particular a clutch plate with a torsional vibration
damper.
A clutch plate for a motor vehicle friction clutch is known from DE-A-39 21
283 (U.S. Pat. No. 5,016,744) in which two lateral discs rigidly connected
to one another are arranged on a hub on either side of a hub disc
non-rotatably connected to the hub, the lateral discs being torsionally
elastically connected to the hub disc via springs. The lateral discs carry
the friction linings of the clutch plate in the conventional manner. One
of the two lateral discs is rotatably mounted on a circular cylindrical
external face of the hub via a plastic ring. The plastic ring has an
annularly closed annular part with which it is inserted into a central
opening of the lateral disc. A web part projecting radially outwardly from
the annular part fixes the plastic ring axially on the lateral disc.
A plurality of blocks project radially inwardly from the annular part and
are separated from one another by radially inwardly issuing radial slots.
The blocks end radially opposite the circular cylindrical external face of
the hub with a cylindrical segment-shaped internal contour. Whereas the
blocks of a first set are radially resilient in design and define an
internal diameter allowing their internal contour to rest without radial
initial tension on the external contour of the hub, the blocks of a second
set are radially non-resilient in design. The blocks of the second set
define a greater internal diameter and form radial stops which limit the
spring travel of the blocks of the first set.
The blocks of the second set continue radially outwardly beyond the annular
part as noses which engage in radial recesses of the central opening of
the lateral disc to prevent rotation of the plastic ring. To guarantee a
non-rotatable fixing of this type, the peripherally located edges of the
recesses have to be produced accurately with low tolerances. However, the
radial boundary of the recesses has relatively great tolerances. In
operation, this means that the non-resilient blocks of the second set can
yield radially outwardly at least in part when the radial spring travel of
the blocks of the first set is used up. This makes it difficult to limit
the spring travel exactly and can damage the plastics ring.
SUMMARY OF THE INVENTION
The invention improves the above-described plastic ring of a clutch plate
so as to guarantee reliable restriction of the spring travel without the
plastic ring being mechanically over-stressed or the production tolerances
of the recesses in the central opening of the lateral disc having to be
altered.
The invention is based on a clutch plate for a motor vehicle friction
clutch, comprising:
a hub concentric to an axis of rotation
a hub disc non-rotatably connected to the hub
lateral discs which are arranged axially on either side of the hub disc,
are rigidly connected to one another, are rotatable relative to the hub
disc, are torsionally elastically coupled to the hub disc by means of
springs and of which one lateral disc has a central opening with which
this lateral disc surrounds a circular cylindrical external face of the
hub,
a plastic ring, radially guiding said one lateral disc on the hub, with an
annularly closed annular part inserted into the central opening of said
one lateral disc, with a web part which projects radially outwardly from
the annular part and forms an axial stop resting on said one lateral disc,
with at least one nose which projects radially outwardl.y from the annular
part and engages in a radial recess of the central opening to prevent
rotation and with a plurality of sets of peripherally distributed blocks
which are separated from one another by radial slots, project radially
inwardly from the annular part and each have a cylindrical segment-shaped
internal contour radially adjacent to the circular cylindrical external
contour of the hub, wherein the blocks of a first set are radially
resilient in design and each have a web which forms the cylindrical
segment-shaped internal contour and extends substantially in the direction
of the axis of rotation, is connected via a connecting region to an axial
edge region of the annular part and rests with the cylindrical
segment-shaped internal contour without radial pretension on the circular
cylindrical external contour of the hub, and wherein the blocks of a
second set are radially non-resilient in design and extend radially
outwardly beyond the annular part to form the nose, wherein the internal
contour of the blocks of the second set define a greater internal diameter
than the blocks of the first set.
The improvement resides in the fact that the blocks of a third set are also
radially non-resilient in design and the internal contour of the blocks of
the third set define an internal diameter which is greater than the
internal diameter defined by the internal contour of the blocks of the
first set but smaller than the internal diameter defined by the internal
contour of the blocks of the second set.
In contrast to the blocks of the second set which pass into the noses, the
blocks of the third set rest directly on the central opening of the
lateral disc and cannot therefore escape. The blocks of the third set
restrict the radial spring travel and are not used to prevent rotation as
the blocks of the second set. The blocks of the second set possibly
additionally come into contact with the hub if the blocks of the third set
are so worn after prolonged operation that their internal diameter
coincides with that of the second set of blocks. From this moment, all
non-resilient blocks participate in the restriction of the spring travel.
In a preferred design, a block from the second or third set follows each
block of the first set alternately. This ensures that a radially
non-resilient block of the second or third set follows on either side of
each radially resilient block of the first set. A uniform distribution of
this type results in balanced force distribution on both the resilient and
the non-resilient blocks.
The first set preferably comprises eight blocks while the second and third
set each have four blocks. The resultant distribution of the blocks in the
peripheral direction guarantees that the load arising between the hub and
the lateral disc is uniformly distributed on the plastic ring. Local
overstressing is therefore ruled out.
The various features of novelty which characterize the invention are
pointed out with particularity in the claims annexed to, and forming part
of, this disclosure. For a better understanding of the invention, its
operating advantages and specific objects attained by its use, reference
should be had to the accompanying drawings and descriptive matter in which
there are illustrated and described preferred embodiments of the invention
.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is an axial longitudinal section through a part of a clutch plate,
partially in schematic form, as viewed along a section line I--I of a
plastic ring of the clutch plate from FIG. 2.
FIG. 2 is an axial section of the plastic ring as viewed from the exterior
of the clutch plate.
FIG. 3 is a lateral view of a detail of a lateral disc of the clutch plate.
DESCRIPTION OF PREFERRED EMBODIMENTS
The clutch plate shown in part in FIG. 1 of a motor vehicle friction clutch
comprises a hub 3 which is concentric to an axis of rotation 1 and from
which a hub disc 5 projects radially. As illustrated, the hub disc 5 can
be integrally connected to the hub 3, however it can also be coupled in
the conventional manner via teeth with a certain rotary play but otherwise
non-rotatably to the hub 3. Two covering plates or lateral discs 7, 9 are
rotatably arranged coaxially to the hub 3 axially on either side of the
hub disc 5. As indicated schematically at 11 in FIG. 1, the lateral discs
7, 9 are rigidly connected to one another, for example by rivets, and
carry friction linings 13 of the clutch plate. Peripherally distributed
springs 15 couple the lateral discs 7, 9 torsionally elastically to the
hub disc 5. Between the hub disc 5 and the lateral discs 7, 9 there are
provided friction devices which, in the embodiment illustrated, comprise a
friction ring 16 arranged between the hub disc 5 and the lateral disc 9, a
friction ring 17 arranged between the hub disc 5 and the lateral disc 7
and a Belleville spring washer 19 which is fixed axially between the
friction ring 17 nd the lateral disc 7 and rests on the friction ring 17
via a thrust ring 21 non-rotatably connected to the lateral disc 7.
The unit comprising the lateral discs 7, 9 is guided radially on a circular
cylindrical external contour 25 of the hub 3 by a plastic ring 23. The
plastics ring 23 is inserted into a central opening 27 in one of the two
lateral discs, the lateral disc 7 in this case, and, as shown most clearly
in FIG. 2, has an annularly closed annular part 29 which is inserted into
the central opening 27 of the lateral disc 7 and, at an axial end region,
has a radially outwardly projecting web part 31 which forms axial st
resting on the lateral disc 7. Peripherally distributed noses 33 project
radially outwardly from the annular part 29, engage in radial recesses 35
(FIG. 3) on the margin of the central opening 27 and prevent rotation of
the plastic ring 23 on the lateral disc 7. The peripherally located edges
37 of the recess 35 enclose the noses 33 with small tolerances. The radial
margin 39 of the recess 35, on the other hand is produced with
comparatively great tolerances.
Three sets of blocks 41, 43 and 45 project radially inwardly from the
annular part 29 to the circular cylindrical contour 25 of the hub 3. All
blocks 41, 43 and 45 have a circular segment-shaped cylindrical internal
contour, the internal contours of the various sets of blocks defining
different internal diameters, as described in detail hereinafter. The
peripherally succeeding blocks 41, 43, 45 are separated by slots 46,
issuing radially inwardly, and each rest with a segment 47 of a circular
cylindrical internal contour radially opposite the circular cylindrical
external contour 25 of the hub 3.
The blocks 41 of a first set are radially resilient in design and, as shown
most clearly in FIG. 1, have a web 49 which extends in the direction of
the axis of rotation 1 and is connected to one of the axial edge regions
of the annular part 29 via an obliquely extending connecting region 51.
The internal diameter D1 (FIG. 2) defined by the internal contour of the
blocks 41 is dimensioned such that the blocks 41 rest without radial
prestress on the external contour 25 of the hub 3.
The blocks 43 of a second set are non-resilient in design and continue
integrally in each case into one of the noses 33 provided on the exterior
of the annular part 29 to prevent rotation. The blocks 45 of the third set
are also non-resilient in design and, in contrast to the blocks 43 which
have no direct radial support on the lateral disc 7 owing to the radial
tolerances of the noses 33 in the recesses 35, rest directly on the edge
of the central opening 27 via the annular part 29. The internal diameter
D3, defined by the internal contour of the blocks 45 of the third set, is
greater than the internal diameter D1 of the blocks 41, and the blocks 45
form radial stops to restrict the spring travel of the radially resilient
blocks 41. The internal diameter D2, defined by the internal contour of
the blocks 43, is greater than the internal diameter D1 of the blocks 41
and also greater than the internal diameter D3 of the blocks 45. This
ensures that the hub 3 initially rests on the non-resilient blocks 45 with
its cylindrical external contour 25 when the spring travel of the blocks
41 is used up. The blocks 43 can only serve to restrict spring travel
after prolonged operation if the blocks 45 are worn and the internal
diameter D3 has therefore become equal to the internal diameter D2. A
certain amount of wear of the plastic ring can therefore be permitted
without impairing its usefulness. The radial movability is invariably
ensured without the plastics ring 23 being overstressed anywhere.
In the embodiment illustrated, a block 43 of the second set or a block 45
of the third set follows a radially resilient block 41 alternately. A
block 43 of the second set is therefore found on one side and a block 45
of the third set on the other side in the peripheral direction on either
side of each block 41. The radial forces acting on the plastic ring 23 are
therefore distributed particularly uniformly over the entire service life
thereof. Eight blocks 41 as well as four respective blocks 43 and 45 are
distributed in the above-mentioned manner in the embodiment illustrated.
While specific embodiments of the invention have been shown and described
in detail to illustrate the application of the inventive principles, it
will be understood that the invention may be embodied otherwise without
departing from such principles.
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